KR20100104412A - Portable electronic nose system - Google Patents

Abstract

PURPOSE: A portable electronic nose system, which accurately detects smell, even when an olfactory is contaminated, is provided to rapidly detect gas in the long time use by correcting a result by comparing a result measured in a sample cell and a result measured in a standard cell. CONSTITUTION: A portable electronic nose system comprises a standard cell(300), a first olfactory sensor(200), a sample cell(500), a second olfactory sensor(600) and a controller(800). An air from which measurement target gas feeder is removed passes through the standard cell. The first olfactory sensor measures the gas density of the air passing through the standard cell. The sample cell passes through the measurement target air. The second olfactory sensor measures the gas density of the measurement target air passing through the sample cell.

Description

Portable electronic nose system

The present invention relates to an electronic nose system, and more particularly to a portable electronic nose system using two cells.

In the case of meat, the time and degree of decay are different depending on the condition before slaughter, post-aging, storage temperature, and meat part, so it is difficult to determine the quality and freshness of the livestock products only by the expiration date during distribution.

Production and distribution information is provided in the production history system, but direct verification of freshness is not possible. In order to prevent food poisoning accidents caused by deteriorated meats, which are poorly quality controlled in the field, scientific and standardized measurement techniques that can be easily used by unskilled people are needed.

According to the present invention, the food smells as the food decays, that is, the specific gaseous component is generated as the food decay, and by measuring the degree of smell (concentration of a specific gaseous component) to determine the deterioration, decay and corruption of the food. Attention was paid to the point which can be measured.

As a technique for easily measuring the smell, Korean Patent No. 10-600334 has been published. As shown in FIG. 1, Korean Patent No. 10-600334 installs an olfactory sensor unit 10 and an electronic nose function performing unit 20 to measure smell in a portable terminal. When the user opens the cover 25 to measure the smell, the smell is introduced into the olfactory sensor unit 10, and the type of the smell in the electronic nose function performing unit 20 using the measured value generated by the olfactory sensor unit 10. And concentration can be measured.

However, the prior art simply has to measure the odor for a number of samples through one sensor unit, there is a problem that can not be accurately measured because the sensor unit is contaminated when used for a long time.

The problem to be solved by the present invention is to provide a portable electronic nose system capable of accurate odor measurement (measurement of the gas component that generates the odor) even if the olfactory sensor is contaminated due to long-term use.

The electronic nose system of the present invention for solving the above problems, the reference cell for passing the air from which the measurement target gas component is removed from the measurement target air; A first olfactory sensor for measuring a gas concentration of air passing through the reference cell; A sample cell for passing the air to be measured; A second olfactory sensor for measuring a gas concentration of air to be measured passing through the sample cell; And simultaneously receiving measurement values from the first olfactory sensor and the second olfactory sensor, and correcting the measurement result measured by the second olfactory sensor by using the measurement result measured by the first olfactory sensor. And a control unit for measuring the concentration of the measurement target gas component.

In addition, the electronic nose system of the present invention may further include a filtering unit for removing the measurement target gas component from the measurement target air, the filtering unit may be an adsorption cloth.

In addition, the electronic nose system of the present invention may further include a regulator for adjusting the amount of air to be measured flowing into the sample cell.

In addition, the electronic nose system of the present invention, the sample cell and the reference cell may further include a pumping unit for introducing the measurement target air, and discharges the introduced air to the outside.

According to the present invention, the reference cell and the sample cell are separated to allow the air from which the odor (gas component) is removed and the air containing the odor (gas component) to pass therethrough, and at the same time, the gas component and the concentration of the reference cell and the sample cell are determined. After the measurement, the result measured in the sample cell is corrected using the result measured in the reference cell, so that even in a long-term use, an accurate and rapid gas component measurement can be obtained.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

2 is a diagram showing the configuration of a portable electronic nose system according to a preferred embodiment of the present invention.

Referring to FIG. 2, the portable electronic nose system of the present invention includes a pumping unit 100, a reference cell 300, a first olfactory sensor 200, a sample cell 500, a second olfactory sensor 600, and a filtering unit. 400, a regulator 700, a controller 800, and a display 900.

When the user wants to measure the gas concentration by using the electronic nose system according to the present invention, the user places the electronic nose system shown in FIG. 2 around the measurement sample, and measures the gas component to be generated in the measurement sample. Measurement is performed while the air to be measured passes through the reference cell 300, the sample cell 500, and the pumping part 100. The function of each component will be described below.

The pumping unit 100 introduces the measurement target air around the measurement sample into the electronic nose system and flows out the air on which the measurement is performed to the outside of the electronic nose system. Specifically, the pumping unit 100 generates a pressure so that the air to be measured flows in the direction of the arrow of FIG. 2, that is, the air passing through the filtering unit 400 passes through the reference cell 300 and flows in from the outside. Pressure is generated so that the measured object air passes through the sample cell 500 and flows out.

The filtering unit 400 is implemented by an adsorption cloth or other means to remove the odor component from the measurement target air introduced into the filtering unit 400 around the measurement sample, and then introduces air from which the odor component is removed into the reference cell 300. Let's do it. In this case, the filtering unit 400 may remove all odor components, but may also be configured to selectively remove only the gas components to be measured currently from among a plurality of gas components included in the measurement target air.

Air introduced into the reference cell 300 from the filtering unit 400 passes through the reference cell 300 and flows out of the reference cell 300. The first olfactory sensor 200 is installed in the reference cell 300 to measure gas from air passing through the reference cell 300, and output the measured value to the controller 800. The measured value measured by the first olfactory sensor 200 is used as a reference value.

Meanwhile, the regulator 700 adjusts the amount of air introduced into the sample cell 500. As shown in FIG. 2, when the reference cell 300 and the sample cell 500 are connected to one and connected to the pumping unit 100, the amount of air flowing into the sample cell 500 is controlled by adjusting the regulator 700. It is possible to adjust, and correspondingly it is possible to adjust the amount of air flowing into the reference cell 300.

The measurement target air introduced into the sample cell 500 from the regulator 700 passes through the sample cell 500 and flows out of the sample cell 500. The second olfactory sensor 600 is installed in the sample cell 500 to measure a gas component from air passing through the sample cell 500, and output the measured value to the controller 800.

The controller 800 controls the pumping unit 100, the regulator 700, and the filtering unit 400 described above, and simultaneously receives measurement values from the first olfactory sensor 200 and the second olfactory sensor 600. . The controller 800 measures the concentration of the target gas component included in the current air by using the measured value input from the second olfactory sensor 600, and outputs the measured result to the display 900 to display to the user. .

At this time, the controller 800 corrects the measured value measured by the second olfactory sensor 600 using the measured value (reference value) input from the first olfactory sensor 200 to more accurately measure the concentration of the gas component. Measure For example, when a plurality of gas components are included in the air to be measured and only the concentration of one specific component is to be measured, the measured values for the specific components may be disturbed due to the other gas components included in the air. In this case, the measured value of the air from which the specific gas component has been removed from the first olfactory sensor 200 is subtracted from the measured value measured by the second olfactory sensor 600 by a ratio that has been experimentally calculated in advance to obtain a more accurate measurement of the gas component. It is possible.

In a preferred embodiment of the present invention, the concentration G of gas is calculated according to Equation 1 below.

Meaning of each variable in Equation 1 is as follows.

Vr: measured value of reference cell

Vsa: Pre-measured value as sample cell measurement value when clean air is poured into sample cell

Vss: Measurement value of the sample cell when a span gas of known concentration is flowed

Va = (Vsa / Vr)

Vs = (Vss / Vr)

Vm: gas of unknown concentration

C: Constant value determined through experiment

On the other hand, the display unit 900 is implemented as a liquid crystal display device to output a gas component and the concentration measurement result of the gas component. When the electronic nose system of the present invention is combined with a portable mobile communication device, the display unit 900 is implemented as a display of the mobile communication device.

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

1 is a diagram illustrating an example of a prior art in which an electronic nose system is coupled to a portable mobile communication terminal.

2 is a view showing the configuration of a portable electronic nose system according to a preferred embodiment of the present invention.

Claims (4)

A reference cell for passing air from which the gas component to be measured is removed from the air to be measured; A first olfactory sensor for measuring a gas concentration of air passing through the reference cell; A sample cell for passing the air to be measured; A second olfactory sensor for measuring a gas concentration of air to be measured passing through the sample cell; And The measurement result measured by the second olfactory sensor is received from the first olfactory sensor and the second olfactory sensor simultaneously, and the measurement result measured by the second olfactory sensor is corrected by using the measured result measured by the first olfactory sensor. An electronic nose system comprising a control unit for measuring the concentration of the measurement target gas component. The method of claim 1, The electronic nose system further comprises a filtering unit for removing the gas component to be measured from the air to be measured. The method of claim 1, Electronic nose system characterized in that it further comprises a regulator for adjusting the amount of air to be measured flowing into the sample cell. The method of claim 1, The electronic nose system further comprises a pumping unit for introducing the measurement target air into the sample cell and the reference cell, and discharges the introduced air to the outside.

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